//==============================================================================
// Copyright 2018-2020 Kitware, Inc., Kitware SAS
// Author: Guilbert Pierre (Kitware SAS)
//         Cadart Nicolas (Kitware SAS)
// Creation date: 2018-03-27
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//     http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//==============================================================================

#ifndef VTK_SLAM_H
#define VTK_SLAM_H

// VTK
#include <vtkPolyDataAlgorithm.h>
#include <vtkSmartPointer.h>

// LOCAL
#include <LidarSlam/Slam.h>

//! Which keypoints' maps to output
enum OutputKeypointsMapsMode
{
  //! No maps output
  NONE = 0,
  //! Output the whole keypoints' maps
  FULL_MAPS = 1,
  //! Output the target sub maps used for the current frame registration
  SUB_MAPS = 2
};

// This custom macro is needed to make the SlamManager time agnostic.
// The SlamManager needs to know when RequestData is called, if it's due
// to a new timestep being requested or due to SLAM parameters being changed.
// By keeping track of the last time the parameters have been modified there is
// no ambiguity anymore. This mecanimsm is similar to the one used by the
// paraview filter PlotDataOverTime.
#define vtkCustomSetMacro(name, type)                                                            \
virtual void Set##name(type _arg)                                                                \
{                                                                                                \
  vtkDebugMacro(<< this->GetClassName() << " (" << this << "): setting " #name " to " << _arg);  \
  if (this->SlamAlgo->Get##name() != _arg)                                                       \
  {                                                                                              \
    this->SlamAlgo->Set##name(_arg);                                                             \
    this->ParametersModificationTime.Modified();                                                 \
  }                                                                                              \
}
#define vtkCustomSetMacroNoCheck(name, type)                                                     \
virtual void Set##name(type _arg)                                                                \
{                                                                                                \
  vtkDebugMacro(<< this->GetClassName() << " (" << this << "): setting " #name " to " << _arg);  \
  this->SlamAlgo->Set##name(_arg);                                                               \
  this->ParametersModificationTime.Modified();                                                   \
}

#define vtkCustomGetMacro(name, type)                                                            \
virtual type Get##name()                                                                         \
{                                                                                                \
  vtkDebugMacro(<< this->GetClassName() << " (" << this << "): returning " << #name " of "       \
                << this->SlamAlgo->Get##name());                                                 \
  return this->SlamAlgo->Get##name();                                                            \
}


#define vtkCustomSetMacroExternalSensor(sensorName, name, type)                                  \
virtual void Set##name(type _arg)                                                                \
{                                                                                                \
  vtkDebugMacro(<< this->GetClassName() << " (" << this << "): setting " #name " to " << _arg);  \
  if (this->Get##name() != _arg)                                                                 \
  {                                                                                              \
    if (this->SlamAlgo->sensorName##HasData())                                                   \
    {                                                                                            \
      this->SlamAlgo->Set##name(_arg);                                                           \
      this->ParametersModificationTime.Modified();                                               \
    }                                                                                            \
  }                                                                                              \
}

#define vtkCustomGetMacroExternalSensor(sensorName, name, type)                                  \
virtual type Get##name()                                                                         \
{                                                                                                \
  if (this->SlamAlgo->sensorName##HasData())                                                     \
  {                                                                                              \
    vtkDebugMacro(<< this->GetClassName() << " (" << this << "): returning " << #name " of "     \
                  << this->SlamAlgo->Get##name());                                               \
    return this->SlamAlgo->Get##name();                                                          \
  }                                                                                              \
  type def;                                                                                      \
  return def;                                                                                    \
}


class vtkSpinningSensorKeypointExtractor;
class vtkTable;

class vtkSlam : public vtkPolyDataAlgorithm
{
public:
  static vtkSlam* New();
  vtkTypeMacro(vtkSlam, vtkPolyDataAlgorithm)
  void PrintSelf(ostream& os, vtkIndent indent) override;

  virtual vtkMTimeType GetMTime() override;

  // ---------------------------------------------------------------------------
  //   General stuff and flags
  // ---------------------------------------------------------------------------

  void Reset();
  // Clear the maps and the logged trajectory
  // but keep all other parameters
  void ClearMaps();

  void RebuildMaps();

  // Initialization
  void SetInitialMap(const std::string& mapsPathPrefix);
  void SetInitialPoseTranslation(double x, double y, double z);
  void SetInitialPoseRotation(double roll, double pitch, double yaw);

  // Getters / Setters
  vtkGetMacro(AutoDetectInputArrays, bool)
  vtkSetMacro(AutoDetectInputArrays, bool)

  vtkGetMacro(TimeToSecondsFactorSetting, double)
  vtkSetMacro(TimeToSecondsFactorSetting, double)

  vtkGetMacro(AdvancedReturnMode, bool)
  virtual void SetAdvancedReturnMode(bool _arg);

  vtkGetMacro(OutputCurrentKeypoints, bool)
  vtkSetMacro(OutputCurrentKeypoints, bool)

  virtual int GetOutputKeypointsMaps();
  virtual void SetOutputKeypointsMaps(int mode);

  vtkGetMacro(MapsUpdateStep, unsigned int)
  vtkSetMacro(MapsUpdateStep, unsigned int)

  vtkGetMacro(OutputKeypointsInWorldCoordinates, bool)
  vtkSetMacro(OutputKeypointsInWorldCoordinates, bool)

  vtkGetMacro(ResetMaps, bool)
  vtkSetMacro(ResetMaps, bool)

  void EnableEdges(bool enable);
  void EnableIntensityEdges(bool enable);
  void EnablePlanes(bool enable);
  void EnableBlobs(bool enable);

  bool areEdgesEnabled();
  bool areIntensityEdgesEnabled();
  bool arePlanesEnabled();
  bool areBlobsEnabled();

  vtkCustomGetMacro(Verbosity, int)
  vtkCustomSetMacro(Verbosity, int)

  vtkCustomGetMacro(NbThreads, int)
  vtkCustomSetMacro(NbThreads, int)

  virtual int GetEgoMotion();
  virtual void SetEgoMotion(int mode);

  virtual int GetUndistortion();
  virtual void SetUndistortion(int mode);

  // Load trajectory from a file and recompute maps
  void SetTrajectory(const std::string& fileName);

  virtual int GetInterpolation();
  virtual void SetInterpolation(int model);

  // Set measurements to Slam algo
  virtual void SetSensorData(const std::string& fileName);

  vtkGetMacro(TrajFrequency, double)
  vtkSetMacro(TrajFrequency, double)

  // ---------------------------------------------------------------------------
  //   Graph parameters
  // ---------------------------------------------------------------------------

  // Check LoggingTimeout is set correctly to ensure the use of pose graph optimization
  void SetUsePoseGraph(bool usePoseGraph);

  // Use the optimized poses from the IMU/SLAM graph to
  // update the trajectory and rebuild the maps (needs GTSAM not G2O)
  void OptimizeGraphWithIMU();

  // Optimize the graph with available information (needs G2O not GTSAM)
  void OptimizeGraph();

  vtkCustomGetMacro(G2oFileName, std::string)
  vtkCustomSetMacro(G2oFileName, std::string)

  vtkCustomGetMacro(FixFirstVertex, bool)
  vtkCustomSetMacro(FixFirstVertex, bool)

  vtkCustomGetMacro(FixLastVertex, bool)
  vtkCustomSetMacro(FixLastVertex, bool)

  vtkCustomGetMacro(CovarianceScale, float)
  vtkCustomSetMacro(CovarianceScale, float)

  vtkCustomGetMacro(NbGraphIterations, int)
  vtkCustomSetMacro(NbGraphIterations, int)

  void EnablePGOConstraintLoopClosure(bool enable);
  void EnablePGOConstraintLandmark(bool enable);
  void EnablePGOConstraintGPS(bool enable);

  bool GetPGOConstraintLoopClosure();
  bool GetPGOConstraintLandmark();
  bool GetPGOConstraintGPS();

  // ---------------------------------------------------------------------------
  //   Loop closure parameters
  // ---------------------------------------------------------------------------

  virtual int  GetLoopDetector();
  virtual void SetLoopDetector(int detector);

  vtkCustomGetMacro(LoopQueryIdx, unsigned int)
  virtual void SetLoopQueryIdx(unsigned int loopClosureQueryIdx);

  vtkCustomGetMacro(LoopRevisitedIdx, unsigned int)
  virtual void SetLoopRevisitedIdx(unsigned int loopClosureRevisitedIdx);

  vtkCustomGetMacro(LoopQueryMapStartRange, double)
  vtkCustomSetMacro(LoopQueryMapStartRange, double)

  vtkCustomGetMacro(LoopQueryMapEndRange, double)
  vtkCustomSetMacro(LoopQueryMapEndRange, double)

  vtkCustomGetMacro(LoopRevisitedMapStartRange, double)
  vtkCustomSetMacro(LoopRevisitedMapStartRange, double)

  vtkCustomGetMacro(LoopRevisitedMapEndRange, double)
  vtkCustomSetMacro(LoopRevisitedMapEndRange, double)

  // Get/Set automatic detection parameters
  vtkCustomGetMacro(LoopGapLength, double)
  vtkCustomSetMacro(LoopGapLength, double)

  vtkCustomGetMacro(LoopSampleStep, double)
  vtkCustomSetMacro(LoopSampleStep, double)

  vtkCustomGetMacro(LoopEvaluationThreshold, double)
  vtkCustomSetMacro(LoopEvaluationThreshold, double)

  // Get/Set Loop closure registration parameters
  vtkCustomGetMacro(LoopEnableOffset, bool)
  vtkCustomSetMacro(LoopEnableOffset, bool)

  vtkCustomGetMacro(LoopICPWithSubmap, bool)
  vtkCustomSetMacro(LoopICPWithSubmap, bool)

  vtkCustomGetMacro(LoopLMMaxIter, unsigned int)
  vtkCustomSetMacro(LoopLMMaxIter, unsigned int)

  vtkCustomGetMacro(LoopICPMaxIter, unsigned int)
  vtkCustomSetMacro(LoopICPMaxIter, unsigned int)

  vtkCustomGetMacro(LoopMaxNeighborsDistance, double)
  vtkCustomSetMacro(LoopMaxNeighborsDistance, double)

  vtkCustomGetMacro(LoopEdgeNbNeighbors, unsigned int)
  vtkCustomSetMacro(LoopEdgeNbNeighbors, unsigned int)

  vtkCustomGetMacro(LoopEdgeMinNbNeighbors, unsigned int)
  vtkCustomSetMacro(LoopEdgeMinNbNeighbors, unsigned int)

  vtkCustomGetMacro(LoopEdgeMaxModelError, double)
  vtkCustomSetMacro(LoopEdgeMaxModelError, double)

  vtkCustomGetMacro(LoopPlaneNbNeighbors, unsigned int)
  vtkCustomSetMacro(LoopPlaneNbNeighbors, unsigned int)

  vtkCustomGetMacro(LoopPlanarityThreshold, double)
  vtkCustomSetMacro(LoopPlanarityThreshold, double)

  vtkCustomGetMacro(LoopPlaneMaxModelError, double)
  vtkCustomSetMacro(LoopPlaneMaxModelError, double)

  vtkCustomGetMacro(LoopBlobNbNeighbors, unsigned int)
  vtkCustomSetMacro(LoopBlobNbNeighbors, unsigned int)

  vtkCustomGetMacro(LoopInitSaturationDistance, double)
  vtkCustomSetMacro(LoopInitSaturationDistance, double)

  vtkCustomGetMacro(LoopFinalSaturationDistance, double)
  vtkCustomSetMacro(LoopFinalSaturationDistance, double)

  // ---------------------------------------------------------------------------
  //   BASE to LIDAR transform
  // ---------------------------------------------------------------------------

  virtual void SetBaseToLidarTranslation(double x, double y, double z);

  virtual void SetBaseToLidarRotation(double rx, double ry, double rz);

  virtual void SetBaseToLidarTransform(std::string filename);

  // ---------------------------------------------------------------------------
  //   Optimization parameters
  // ---------------------------------------------------------------------------

  vtkCustomGetMacro(TwoDMode, bool)
  vtkCustomSetMacro(TwoDMode, bool)

  // Get/Set EgoMotion
  vtkCustomGetMacro(EgoMotionLMMaxIter, unsigned int)
  vtkCustomSetMacro(EgoMotionLMMaxIter, unsigned int)

  vtkCustomGetMacro(EgoMotionICPMaxIter, unsigned int)
  vtkCustomSetMacro(EgoMotionICPMaxIter, unsigned int)

  vtkCustomGetMacro(EgoMotionMaxNeighborsDistance, double)
  vtkCustomSetMacro(EgoMotionMaxNeighborsDistance, double)

  vtkCustomGetMacro(EgoMotionEdgeNbNeighbors, unsigned int)
  vtkCustomSetMacro(EgoMotionEdgeNbNeighbors, unsigned int)

  vtkCustomGetMacro(EgoMotionEdgeMinNbNeighbors, unsigned int)
  vtkCustomSetMacro(EgoMotionEdgeMinNbNeighbors, unsigned int)

  vtkCustomGetMacro(EgoMotionEdgeMaxModelError, double)
  vtkCustomSetMacro(EgoMotionEdgeMaxModelError, double)

  vtkCustomGetMacro(EgoMotionPlaneNbNeighbors, unsigned int)
  vtkCustomSetMacro(EgoMotionPlaneNbNeighbors, unsigned int)

  vtkCustomGetMacro(EgoMotionPlanarityThreshold, double)
  vtkCustomSetMacro(EgoMotionPlanarityThreshold, double)

  vtkCustomGetMacro(EgoMotionPlaneMaxModelError, double)
  vtkCustomSetMacro(EgoMotionPlaneMaxModelError, double)

  vtkCustomGetMacro(EgoMotionInitSaturationDistance, double)
  vtkCustomSetMacro(EgoMotionInitSaturationDistance, double)

  vtkCustomGetMacro(EgoMotionFinalSaturationDistance, double)
  vtkCustomSetMacro(EgoMotionFinalSaturationDistance, double)

  // Get/Set Localization
  vtkCustomGetMacro(LocalizationLMMaxIter, unsigned int)
  vtkCustomSetMacro(LocalizationLMMaxIter, unsigned int)

  vtkCustomGetMacro(LocalizationICPMaxIter, unsigned int)
  vtkCustomSetMacro(LocalizationICPMaxIter, unsigned int)

  vtkCustomGetMacro(LocalizationMaxNeighborsDistance, double)
  vtkCustomSetMacro(LocalizationMaxNeighborsDistance, double)

  vtkCustomGetMacro(LocalizationEdgeNbNeighbors, unsigned int)
  vtkCustomSetMacro(LocalizationEdgeNbNeighbors, unsigned int)

  vtkCustomGetMacro(LocalizationEdgeMinNbNeighbors, unsigned int)
  vtkCustomSetMacro(LocalizationEdgeMinNbNeighbors, unsigned int)

  vtkCustomGetMacro(LocalizationEdgeMaxModelError, double)
  vtkCustomSetMacro(LocalizationEdgeMaxModelError, double)

  vtkCustomGetMacro(LocalizationPlaneNbNeighbors, unsigned int)
  vtkCustomSetMacro(LocalizationPlaneNbNeighbors, unsigned int)

  vtkCustomGetMacro(LocalizationPlanarityThreshold, double)
  vtkCustomSetMacro(LocalizationPlanarityThreshold, double)

  vtkCustomGetMacro(LocalizationPlaneMaxModelError, double)
  vtkCustomSetMacro(LocalizationPlaneMaxModelError, double)

  vtkCustomGetMacro(LocalizationBlobNbNeighbors, unsigned int)
  vtkCustomSetMacro(LocalizationBlobNbNeighbors, unsigned int)

  vtkCustomGetMacro(LocalizationInitSaturationDistance, double)
  vtkCustomSetMacro(LocalizationInitSaturationDistance, double)

  vtkCustomGetMacro(LocalizationFinalSaturationDistance, double)
  vtkCustomSetMacro(LocalizationFinalSaturationDistance, double)

  vtkCustomGetMacroExternalSensor(WheelOdom, WheelOdomWeight, double)
  vtkCustomSetMacroExternalSensor(WheelOdom, WheelOdomWeight, double)

  vtkCustomGetMacroExternalSensor(WheelOdom, WheelOdomRelative, bool)
  vtkCustomSetMacroExternalSensor(WheelOdom, WheelOdomRelative, bool)

  vtkCustomGetMacroExternalSensor(Gravity, GravityWeight, double)
  vtkCustomSetMacroExternalSensor(Gravity, GravityWeight, double)

  vtkCustomGetMacroExternalSensor(Imu, ImuWeight, double)
  vtkCustomSetMacroExternalSensor(Imu, ImuWeight, double)

  void SetImuGravity(double x, double y, double z);

  vtkCustomGetMacro(ImuResetThreshold, unsigned int)
  vtkCustomSetMacro(ImuResetThreshold, unsigned int)

  vtkCustomGetMacro(ImuUpdate, bool)
  vtkCustomSetMacro(ImuUpdate, bool)

  vtkCustomGetMacroExternalSensor(Pose, PoseWeight, double)
  vtkCustomSetMacroExternalSensor(Pose, PoseWeight, double)

  vtkCustomGetMacro(SensorTimeOffset, double)
  vtkCustomSetMacro(SensorTimeOffset, double)

  vtkCustomGetMacro(SensorTimeThreshold, double)
  vtkCustomSetMacro(SensorTimeThreshold, double)

  vtkCustomGetMacro(SensorMaxMeasures, unsigned int)
  vtkCustomSetMacro(SensorMaxMeasures, unsigned int)

  void SetSensorTimeSynchronization(int mode);

  // ---------------------------------------------------------------------------
  //   Keypoints extractor, Key frames and Maps parameters
  // ---------------------------------------------------------------------------

  // Keypoints extractor
  vtkGetObjectMacro(KeyPointsExtractor, vtkSpinningSensorKeypointExtractor)
  virtual void SetKeyPointsExtractor(vtkSpinningSensorKeypointExtractor*);

  // Key frames
  vtkCustomGetMacro(KfDistanceThreshold, double)
  vtkCustomSetMacro(KfDistanceThreshold, double)

  vtkCustomGetMacro(KfAngleThreshold, double)
  vtkCustomSetMacro(KfAngleThreshold, double)

  // Set RollingGrid Parameters

  virtual unsigned int GetMapUpdate();
  virtual void SetMapUpdate(unsigned int mode);

  vtkCustomGetMacro(VoxelGridDecayingThreshold, double)
  vtkCustomSetMacro(VoxelGridDecayingThreshold, double)

  virtual int GetVoxelGridSamplingMode (LidarSlam::Keypoint k) const;
  virtual void SetVoxelGridSamplingMode(LidarSlam::Keypoint k, int sm);
  virtual double GetVoxelGridLeafSize(LidarSlam::Keypoint k) const;
  virtual void SetVoxelGridLeafSize(LidarSlam::Keypoint k, double s);

  // For edges
  virtual int GetVoxelGridSamplingModeEdges() const {return this->GetVoxelGridSamplingMode(LidarSlam::EDGE);}
  virtual void SetVoxelGridSamplingModeEdges(int sm)  {this->SetVoxelGridSamplingMode(LidarSlam::EDGE, sm);}
  virtual double GetVoxelGridLeafSizeEdges() const {return this->GetVoxelGridLeafSize(LidarSlam::EDGE);}
  virtual void SetVoxelGridLeafSizeEdges(double s) {this->SetVoxelGridLeafSize(LidarSlam::EDGE, s);}

  // For intensity edges
  virtual int GetVoxelGridSamplingModeIntensityEdges() const {return this->GetVoxelGridSamplingMode(LidarSlam::INTENSITY_EDGE);}
  virtual void SetVoxelGridSamplingModeIntensityEdges(int sm)  {this->SetVoxelGridSamplingMode(LidarSlam::INTENSITY_EDGE, sm);}
  virtual double GetVoxelGridLeafSizeIntensityEdges() const {return this->GetVoxelGridLeafSize(LidarSlam::INTENSITY_EDGE);}
  virtual void SetVoxelGridLeafSizeIntensityEdges(double s) {this->SetVoxelGridLeafSize(LidarSlam::INTENSITY_EDGE, s);}

  // For planes
  virtual int GetVoxelGridSamplingModePlanes() const {return this->GetVoxelGridSamplingMode(LidarSlam::Keypoint::PLANE);}
  virtual void SetVoxelGridSamplingModePlanes(int sm) { this->SetVoxelGridSamplingMode(LidarSlam::Keypoint::PLANE, sm);}
  virtual double GetVoxelGridLeafSizePlanes() const {return this->GetVoxelGridLeafSize(LidarSlam::Keypoint::PLANE);}
  virtual void SetVoxelGridLeafSizePlanes(double s) {this->SetVoxelGridLeafSize(LidarSlam::Keypoint::PLANE, s);}

  // For blobs
  virtual int GetVoxelGridSamplingModeBlobs() const {return this->GetVoxelGridSamplingMode(LidarSlam::Keypoint::BLOB);}
  virtual void SetVoxelGridSamplingModeBlobs(int sm) {this->SetVoxelGridSamplingMode(LidarSlam::Keypoint::BLOB, sm);}
  virtual double GetVoxelGridLeafSizeBlobs() const {return this->GetVoxelGridLeafSize(LidarSlam::Keypoint::BLOB);}
  virtual void SetVoxelGridLeafSizeBlobs(double s) {this->SetVoxelGridLeafSize(LidarSlam::Keypoint::BLOB, s);}

  vtkCustomSetMacroNoCheck(VoxelGridSize, int)
  vtkCustomSetMacroNoCheck(VoxelGridResolution, double)

  vtkCustomSetMacroNoCheck(VoxelGridMinFramesPerVoxel, unsigned int)

  // ---------------------------------------------------------------------------
  //   Confidence estimator parameters
  // ---------------------------------------------------------------------------

  vtkCustomGetMacro(OverlapSamplingRatio, double)
  virtual void SetOverlapSamplingRatio (double ratio);

  // Motion constraints
  virtual void SetAccelerationLimits(float linearAcc, float angularAcc);
  virtual void SetVelocityLimits(float linearVel, float angularVel);
  virtual void SetPoseLimits(float position, float orientation);

  virtual void SetLoggingTimeout(double loggingTimeout);
  vtkCustomGetMacro(LoggingTimeout, double)

  vtkGetMacro(ConfidenceWindow, unsigned int)
  virtual void SetConfidenceWindow (unsigned int window);

  vtkCustomGetMacro(OverlapDerivativeThreshold, double)
  vtkCustomSetMacro(OverlapDerivativeThreshold, double)

  vtkCustomGetMacro(PositionErrorThreshold, double)
  vtkCustomSetMacro(PositionErrorThreshold, double)

  vtkGetMacro(RecoveryTime, float)
  vtkSetMacro(RecoveryTime, float)

  vtkCustomGetMacro(FailureDetectionEnabled, bool)
  virtual void SetFailureDetectionEnabled(bool failDetect);

protected:
  vtkSlam();

  int FillInputPortInformation(int port, vtkInformation* info) override;
  int RequestData(vtkInformation*, vtkInformationVector**, vtkInformationVector*) override;

private:
  vtkSlam(const vtkSlam&) = delete;
  void operator=(const vtkSlam&) = delete;

  // ---------------------------------------------------------------------------
  //   Useful helpers
  // ---------------------------------------------------------------------------

  // Identify input arrays to use
  void IdentifyInputArrays(vtkPolyData* poly, vtkTable* calib);

  // Convert LiDAR calibration to laser id mapping
  std::vector<size_t> GetLaserIdMapping(vtkTable* calib);

  // Create polydata with trajectory arrays and points
  vtkSmartPointer<vtkPolyData> CreateInitTrajectory();

  // Init/reset the output SLAM trajectory
  // If endTime is set, remove the newest poses after endTime
  void ResetTrajectory(double endTime = -1.);

  // Add a SLAM pose and covariance in WORLD coordinates to Trajectory.
  void AddPoseToTrajectory(const LidarSlam::LidarState& state);

  // Add current SLAM pose and covariance in WORLD coordinates to Trajectory.
  void AddLastPosesToTrajectory();

  // Convert VTK PolyData to PCL pointcloud
  // Returns true if all input points are valid (null coordinates), false otherwise
  bool PolyDataToPointCloud(vtkPolyData* poly,
                            LidarSlam::Slam::PointCloud::Ptr pc,
                            const std::vector<size_t>& laserIdMapping) const;

  // Convert PCL pointcloud to VTK PolyData
  void PointCloudToPolyData(LidarSlam::Slam::PointCloud::Ptr pc,
                            vtkPolyData* poly) const;

  // Fill calibration arg with the calibration supplied in fileName file
  // Filename must be a .mat file with matrix saved as numbers spaced by empty char
  // Example :
  // 0.707107 0.640856 0.298836 -0.043362
  // -0.707107 0.640856 0.298836 0.032025
  // 0.000000 -0.422618 0.906308 -0.072949
  // 0.000000 0.000000 0.000000 1.000000
  bool GetCalibrationMatrix(const std::string& fileName, Eigen::Isometry3d& calibration) const;

  // ---------------------------------------------------------------------------
  //   Member attributes
  // ---------------------------------------------------------------------------

protected:

  // Keeps track of the time the parameters have been modified
  // This will enable the SlamManager to be time-agnostic
  // MTime is a much more general mecanism so we can't rely on it
  vtkTimeStamp ParametersModificationTime;

  std::unique_ptr<LidarSlam::Slam> SlamAlgo;
  vtkSpinningSensorKeypointExtractor* KeyPointsExtractor = nullptr;

private:

  // Member to store the current time
  double FrameTime = -1.;
  std::map<LidarSlam::Keypoint, vtkSmartPointer<vtkPolyData>> CacheMaps;

  // Polydata which represents the computed trajectory
  vtkSmartPointer<vtkPolyData> Trajectory;

  // If enabled, advanced return mode will add arrays to outputs showing some
  // additional results or info of the SLAM algorithm such as :
  //  - Trajectory : matching summary, localization error summary
  //  - Output transformed frame : neighborhoods angle, intensity gap, depth gap, space gap
  //  - Extracted keypoints : ICP matching results
  bool AdvancedReturnMode = false;

  // Allows to choose which map keypoints to output
  OutputKeypointsMapsMode OutputKeypointsMaps = FULL_MAPS;

  // Update keypoints maps only each MapsUpdateStep frame
  // (ex: every frame, every 2 frames, 3 frames, ...)
  unsigned int MapsUpdateStep = 1;

  // If enabled, SLAM filter will output keypoints extracted from current
  // frame. Otherwise, these filter outputs are left empty to save time.
  bool OutputCurrentKeypoints = true;

  // If disabled, return raw keypoints extracted from current frame in BASE
  // coordinates, without undistortion. If enabled, return keypoints in WORLD
  // coordinates, optionally undistorted if undistortion is activated.
  // Only used if OutputCurrentKeypoints = true.
  bool OutputKeypointsInWorldCoordinates = true;

  // Arrays to use (depending on LiDAR model) to fill points data
  bool AutoDetectInputArrays = true;   ///< If true, try to auto-detect arrays to use. Otherwise, user needs to specify them.
  std::string TimeArrayName;           ///< Point measurement timestamp
  std::string IntensityArrayName;      ///< Point intensity/reflectivity values
  std::string LaserIdArrayName;        ///< Laser ring id
  std::string VerticalCalibArrayName;  ///< Calibration column used to sort laser rings by elevation angle
  double TimeToSecondsFactor;          ///< Coef to apply to TimeArray values to express time in seconds
  double TimeToSecondsFactorSetting;   ///< Duplicated parameter used to store the value set by user

  // SLAM initialization
  std::string InitMapPrefix; ///< Path prefix of initial maps
  Eigen::Vector6d InitPose;  ///< Initial pose of the SLAM

  // Internal variables to store confidence parameters when advanced
  // return mode and failure detection are disabled.
  float OverlapSamplingRatio = 0.25f;
  unsigned int ConfidenceWindow = 10;

  // In case of failure, duration to come back in time to previous state
  float RecoveryTime = 1.f;

  // Boolean to decide if reset the maps before rebuild the maps
  bool ResetMaps = false;

  // Boolean to decide whether or not to use the pose graph
  bool UsePoseGraph = false;

  // Choose whether to synchronize on network packet
  // reception time or on Lidar frame header time
  bool SynchronizeOnPacket = false;

  // Sensor file name stored to reload the external sensor data after reset
  std::string ExtSensorFileName;

  // Output trajectory require frequency (Hz)
  double TrajFrequency = -1;
};

#endif // VTK_SLAM_H
